Dual Crosslinked Gelatin Methacryloyl Hydrogels for Photolithography and 3D Printing

Gelatin methacryloyl (GelMA) hydrogels have been used in tissue engineering and regenerative medicine because of their biocompatibility, photopatternability, printability, and tunable mechanical and rheological properties. However, low mechanical strength limits their applications in controlled drug release, non-viral gene therapy, and tissue and disease modeling. In this work, a dual crosslinking method for GelMA is introduced. First, photolithography was used to pattern the gels through the crosslinking of methacrylate incorporated amine groups of GelMA. Second, a microbial transglutaminase (mTGase) solution was introduced in order to enzymatically crosslink the photopatterned gels by initiating a chemical reaction between the glutamine and lysine groups of the GelMA hydrogel. The results showed that dual crosslinking improved the stiffness and rheological properties of the hydrogels without affecting cell viability, when compared to single crosslinking with either ultraviolet (UV) exposure or mTGase treatment. Our results also demonstrate that when treated with mTGase, hydrogels show decreased swelling properties and better preservation of photolithographically patterned shapes. Similar effects were observed when three dimensional (3D) printed and photocrosslinked substrates were treated with mTGase. Such dual crosslinking methods can be used to improve the mechanical properties and pattern fidelity of GelMA gels, as well as dynamic control of the stiffness of tissue engineered constructs

Cardiac Cell Patterning on Customized Microelectrode Arrays for Electrophysiological Recordings

Cardiomyocytes (CMs) and fibroblast cells are two essential elements for cardiac tissue structure and function. The interactions between them can alter cardiac electrophysiology and thus contribute to cardiac diseases, such as arrhythmogenesis. One possible explanation is that fibroblasts can directly affect cardiac electrophysiology through electrical coupling with CMs. Therefore, detecting the electrical activities in the CM-fibroblast network is vital for understanding the coupling dynamics among them. Current commercialized platforms for studying cardiac electrophysiology utilize planar microelectrode arrays (MEAs) to record the extracellular field potential (FP) in real-time, but the prearranged electrode configuration highly limits the measurement capabilities at specific locations. Here, we report a custom-designed MEA device with a novel micropatterning method to construct a controlled network of neonatal rat CMs (rCMs) and fibroblast connections for monitoring the electrical activity of rCM-fibroblast co-cultures in a spatially controlled fashion. For the micropatterning of the co-culture, surface topographical features and mobile blockers were used to control the initial attachment locations of a mixture of rCMs and fibroblasts, to form separate beating rCM-fibroblast clusters while leaving empty space for fibroblast growth to connect these clusters. Once the blockers are removed, the proliferating fibroblasts connect and couple the separate beating clusters. Using this method, electrical activity of both rCMs and human-induced-pluripotent-stem-cell-derived cardiomyocytes (iCMs) was examined. The coupling dynamics were studied through the extracellular FP and impedance profile recorded from the MEA device, indicating that the fibroblast bridge provided an RC-type coupling of physically separate rCM-containing clusters and enabled synchronization of these clusters

A novel construct as a cell carrier for tissue engineering

A 3D scaffold, in the form of a foam, with the top surface carrying a micropattern, was constructed from biodegradable polyesters poly(3-hydroxybutyric acid-co-3-hydroxyvaleric acid) (PHBV) and poly(L-lactide-co-D, L-lactide) (P(L/DL)LA) to serve as a substitute for the extracellular matrix (ECM) of tissues with more than one cell type. The construct was tested in vitro for engineering of such tissues using fibroblasts (3T3) and epithelial cells ( retinal pigment epithelial cells, D407). The patterned surface was seeded with D407 cells and the foam was seeded with 3T3 cells to represent a tissue with two different cell types. To improve cell adhesion, the construct was treated with fibronectin. The cells were seeded on the construct in a sequence allowing each type time for adhesion. Cell proliferation, studied by MTS assay, was significantly higher than that of tissue culture polystyrene control by day 14. Scanning electron and fluorescence microscopy showed that the foam side of the construct was highly porous and the pores were interconnected and this allowed cell mobility and proliferation. Immunostaining showed collagen deposition, indicating the secretion of the new ECM by the cells. On the film side of the construct D407 cells formed piles in the grooves and covered the surface completely. It was concluded that the 3D P(L/DL)LA-PHBV construct with one micropatterned surface has a serious potential for use as a tissue engineering carrier in the reconstruction of complex tissues with layered organization and different types of cells in each region

Influence of oxygen plasma modification on surface free energy of PMMA films and cell attachment

For any biomaterial placed into a biological medium, the surface properties of the material, such as porosity, crystallinity, presence and distribution of electrical charge and functional groups are very critical parameters that determine the acceptance or rejection of the material. Applications, especially tissue engineering require some surface modifications at the molecular level without disturbing the bulk properties of the implants in order to enhance the cell attachment on the material. An appropriate technique is the application of glow discharge plasma which employs no solvents, takes place at ambient temperatures, and alterations take place only at the surface by changing the surface chemistry along with surface free energy (SFE) and efficiency for cell-material interaction. In this study, poly(methyl methacrylate) (PMMA) film surfaces were modified with oxygen plasma. SFE and its dispersive and polar (acidic-basic) components of the modified surfaces were calculated by means of several theoretical approaches including geometric mean, harmonic mean and acid-base equations. The relation between SFE and its dispersive and polar components and cell attachment on surfaces were studied. The highest 3T3 cell attachment was obtained for the surface with the total SFE of 61.77 mJ/m(2) and polar component of 50.91 mJ/m(2) according to Geometric mean. The total SFE of this surface was calculated to be 61.06 mJ/m(2) and the polar component as 40.96 mJ/m(2) using the Harmonic mean method